JPH09507951A - Crosstalk reduction connector - Google Patents

Abstract

(57) [Summary] The electrical connector has four contacts (2, 3, 4, 5) extending between the input terminal (18) and the output terminal (13). In order to reduce the interference between the pairs of contacts, the farthest terminals (3 & 5,4 & 6) of the differently assigned signal transmission pairs (4 & 5,3 & 6) of the contacts are overlapped between them. Capacitive coupling is generated in and the crosstalk induced between the terminals (3 & 4,5 & 6) closest to each other and the opposite crosstalk are induced.

Description

Description: FIELD OF THE INVENTION The present invention relates to electrical connectors in which crosstalk between two or more pairs of signal transmission contacts is reduced. Connecting a large number of conductor pairs, where each pair is required to carry an individual signal due to the risk of electromagnetic cross-coupling of the signals due to electrostatic (capacitive) or magnetic (inductive) coupling There are problems with connectors designed to. Such cross-coupling is called crosstalk and worsens as the frequency of the signal increases. Interference occurs as a result of capacitance and inductive coupling between the closest lines of a balanced two-wire pair and suppresses the effect of cancellation of opposite phases and the farthest lines of another pair. As a result, this effectively creates a capacitance difference between each line of each pair and the line of another pair. For example, the contacts 1 and 2 form an orange pair, the contacts 3 and 6 form a green pair, the contacts 4 and 5 form a blue pair, and the contacts 7 and 8 form a brown pair. For 8 contacts in the connector, the problem is sometimes exacerbated by wiring conventions in, for example, conventional EIA / TIA 568B wiring. Such sequence interference is predominant between the blue and green pairs because each line of each pair is located adjacent to the lines of another pair and there are electrostatic and electromagnetic couplings between them. It will be appreciated that there are problems. There is also some binding between the green pair and both the orange and brown pairs because one line of each pair is located adjacent to one line of another pair. Attempts have been made to reduce the effects of crosstalk in adjacent lines of electrical connectors. For example, European Patent Application No. 93301116.5 (0558225A1) of AT & T Corp. discloses that adjacent terminals of a connector induce interference in opposite phases in opposite halves of a contact to effect erase. , A device is described in which the terminals extend in a spaced array up to half the distance and are crossed over by a concave bend in the middle of the ends of the terminals so that they extend from the half position in the opposite array. There is. Such a device is difficult to manufacture in that it requires a concave bend connection and the intersection is very critical. Another technique is Siemens European Patent Application No. 92112808.8 (0525703A1) which uses a printed circuit board in which the connector is double crossed with the disturbing line so that cross-phase anti-phase coupling is performed for erasure. It is described in the book. This device requires both a printed circuit board and numerous crossing devices on the board. Another device is described in which a discrete capacitive or inductive coupling between a pair of undisturbed lines to a line subject to interference is provided to introduce opposing interference elements. The use of discrete elements is inconvenient and expensive. The present invention provides an electrical connector that is reliable, relatively easy to manufacture, and that does not use discrete elements to provide interference compensation. According to the invention, in an electrical connector comprising four or more contacts extending between an input terminal and an output terminal, the overlap of the furthest contacts of different specific assigned signal transmission pairs of said contacts, It is configured to cause capacitive coupling between them to induce interference and reverse interference induced between the closest contacts of different assigned signaling pairs and to reduce the overall interference. Is characterized by. Each of the furthest contacts may include a lateral extension that overlaps another cooperating contact of another pair to create overlap and capacitive coupling between them. The other of the furthest contacts may have large surface area portions with overlapping lateral extensions, thereby increasing capacitive coupling between them. In this way, the capacitance difference between the cooperating contacts and each contact of another pair is reduced, or ideally zeroed. The contacts are transversely spaced from the connector, with the furthest ones of the contacts being assigned as one signal transmission pair, with the laterally extending portions extending inward. The electrical connector may include a number of contacts, any four or more of said contacts selected as a pair being overlapped with another pair of furthest contacts from each other, between them. Capacitive coupling may be created at to induce interference that is opposite to that induced between another pair of closest contacts. In another embodiment of the invention, two additional signaling pairs of contacts are arranged, one on each side of the four contacts, the outer contacts of the four contacts being the closest contacts. And the opposite interference induced between the outermost contact and the nearest terminal of the additional pair by overlapping the furthest contacts of the other pair to create a coupling between them. Is configured to induce. A number of contacts may be provided on each side of the isolation device that forms a dielectric between the overlapping contacts. The separating device may be a polyimide thin film. In order to more readily understand the present invention and various other preferred features thereof, embodiments of the present invention are described below by way of example only with reference to the drawings. FIG. 1 is a schematic diagram showing the main problems of interference occurring in eight contactor connectors. FIG. 2 is a plan view of a lead frame that provides the six terminals of a connector constructed in accordance with the present invention. FIG. 3 is a plan view of a second lead frame that provides two additional terminals for a connector constructed in accordance with the present invention. FIG. 4 is a plan view showing an arrangement of the lead frames of FIG. 3 attached to both sides of an insulating dielectric thin film. 5 is an exploded view of the element portion of a completed connector including the apparatus of FIG. 4 and using features of the present invention. FIG. 6 shows the element portion of the assembled connector of FIG. 5 ready for connecting insulated wires. Referring to FIG. 1, eight terminals in a line connector intended for use with practical EIA / TIA568B wiring are shown. Lines 4 and 5 and 3 and 6 are in close proximity to each other and electromagnetic interference between them is induced by the electromagnetic coupling of the capacitive elements simulated by capacitors C ₁ and C ₂ . To compensate for such interference, the present invention induces interference between 3 and 5 and 4 and 6, which interference is opposite in phase to unwanted interference induced between adjacent lines. Is. This can be done by increasing the capacitive coupling between 3 and 5 and 4 and 6, shown as dashed lines and shown as C ₁ 'and C ₂ ' respectively. As represented by C ₃ and C _4, there is interference in between the lines 2 and 3 and 6 and 7 of the pair of adjacent terminals, which is shown in broken lines, C ₃ 'and C ₄ It can be similarly compensated by increasing the capacitive coupling between 1 and 3 and 6 and 7, respectively, as indicated by '. The present invention is concerned with making such compensation in a connector having four or more terminals. Referring to FIG. 2, leads formed by pressing from a thin metal sheet such as beryllium-copper to form six terminals labeled 1,2,4,5,7,8. The frame 10 is shown in plan view. FIG. 3 shows a plan view of another lead frame 11 similarly formed to form two terminals 3 and 6. In both leadframes, one end of each terminal is formed as an elongated tail 12, the tails extending in a substantially parallel arrangement and the other end separated from the siderail 14. It is sometimes provided with an elongated cutout 13 which forms the fork of the insulation displacement connector. In FIG. 2 it can be seen that terminals 1, 4, 5 and 8 have large width and surface area portions 15A, 15B, 15C and 15D, respectively, which portions, as seen in FIG. And 6 are designed to cooperate with the lateral extensions 16A, 16B, 16C and 16D, respectively. Referring to FIG. 4, there is shown in plan view how two leadframes are separated by an insulating film 17 and mounted so that one overlaps the other. In the figure, the leadframe 10 is located at the bottom and is separated from the leadframe 11 by a transparent membrane for ease of illustration. The thin film may be any suitable dielectric material, such as, for example, the polyimide marketed under the trade name Kapton. The thickness of this film is 0.003 inches. Exactly limited thickness, dielectric constant and overlap control are important when effective interference cancellation is achieved. The frame is fixed to the thin film with an adhesive, for example by forming an acrylic coating on both sides of the thin film and fixing the frame thereto by heat bonding. It can be seen that in the drawing, the lateral extensions 16A, 16B, 16C and 16D respectively overlying the portions 15A, 15B, 15C and 15D are hatched to aid in identification. The central part, which is connected to the insulating film, is shown in FIG. 5 and is designated by the reference numeral 20 and is housed in a plastic material in the form of a substantially rectangular block with eight parallel elongated slots 21. These slots are dead ends at one end to receive the insulated wires of the connecting cable. After containment, the rails of the leadframe are cut off to release the tail 12 and open the ends of the cutout 13 to limit the insulation displacement fork 22. The fork end is bent upwards at a right angle as shown in the drawing and the tail 12 is bent downwards and backwards so that it is inclined downwards with respect to the bottom of the block 20. From FIG. 2, the cutout 13 is properly cut while separated from the rails of the leadframe to produce rows of forks of different height when bent, as will be described below. It will be appreciated that the terminals are relatively displaced in the longitudinal direction of the terminals so as to limit the forks protruding by different distances to facilitate the bonding of the insulated wires. Various additional elements and their connections are described below with reference to the exploded view of FIG. A strain relief element 23, similar in shape to a rectangular block, is provided having a slot 24A similar to slot 21, which receives and supports an insulation displacement connector fork 22 and an insulated wire. As can be seen, the strain relief element 23 effectively forms an extension of the block when the insulating displacement fork 22 is placed in its slot. The cast plastic housing 24 has an upper portion with a recess 25 on one side shaped to allow slidable insertion of the block 20 and strain relief element 23. The bottom of the recess 25 is provided with eight parallel slots 26 extending from the insertion end along the recess and spaced at intervals equal to the spacing of the tails 12 emerging from the block 20. The slot extends through a recess in the bottom of the housing, the housing having an inlet on the opposite side for receiving a cooperating connector. The slots 26 each function to receive the tail 12 when the tail end of the block 20 is inserted into the recess 25, guide the tails during insertion, and separate them after insertion, so that the tails act as mating connectors. The bottom of the cooperating housing is held in a tilted configuration as a contact in the recess. The opposing walls of the recess 25 and the strain relief element 23 each comprise mutually connectable latch elements, which in the described embodiment consist of protrusions 27 tapering inwardly on the opposing walls of the recess 25, When the insertion into the recess 25 is completed, the both ends of the protrusion are coupled to the recesses 28 provided on both side surfaces of the strain relaxation element 23 by the snap operation. Instead of providing cooperating latch elements 28 on strain relief elements 23, they may be provided on opposite sides of block 20. The housing 24 also comprises an upwardly projecting lid 29, which is formed during the casting of the housing, is joined with the upper part of the housing at the hinge line 30 and is fixed in the open position by the side connection part 31. The side connection part 31 is cut off before closing the lid. The lid 29 is aligned with the slots 21, 24A and pushes the insulated wires into the insulation displacement connector fork 22 when they are located in the slots, and when the lid is closed the insulated wires are completely closed. Eight elongated protrusions 32 that function to clamp the. An outer shell 33 formed of metal or plastic and shaped to allow the hinged end of the housing 24 to be snugly inserted is also provided. After inserting the block 20 and the strain relief element 23 into the housing 24, and then placing the wire in the slot 21 of the block 20 and the slot 24A of the strain relief element 23, simply push the housing 24 into the shell to form an insulation displacement connector. The wire is effectively connected, and this action closes the lid and pushes the insulated wire into the fork 22 with the protrusion 32, thereby performing an insulating displacement and connection to the wire and also of the strain relief element 23. Insulation of the wire pushed into slot 24A helps hold the wire. Due to the different heights of the insulation displacement connector forks, some of the wires are pushed into the connector before others, reducing the force required to close the lid and allowing the insulation displacement to proceed sequentially. Be seen. The shell acts as an electrical shield for the connector and is additionally shielded by the metal cable end shield 34 and the securing clip 35. FIG. 6 shows the assembled connector element ready to receive an insulated wire. It has been found that interference is best compensated when the overlapping lateral extensions 16A-16D and the wide portions 15A-15D are provided as close to the tail 12 as possible. Although the described embodiment uses four pairs of wires, the present invention does not contemplate any connector containing more than one pair such as 3, 6, 4 and 5 where interference is required to be reduced. It will be appreciated that it is valid for and can be used in connectors with multiple pairs. In this regard, interference is a problem in all structures where contacts are paired. For simplicity, consider the four contacts in the line connector, which are sequentially numbered 1 to 4, and the pairs are worst case 1 and 4, 2 and 3 (3 and 6, in the embodiments described above. (As well as 4 and 5) but can be shown as 1 and 2, 3 and 4 or 1 and 3, 2 and 4. In each case, there are wires in close proximity to each other that are associated with different pairs, and interference reduction or cancellation according to the techniques of the present invention can occur. Such a structure is considered to be within the technical scope of the present invention. The principles of the present invention are applicable to connectors with multiple contacts, and there is the potential for interference between each pair of contacts and all other pairs of contacts, and the principles of the present invention apply to each pair of contacts. It is applicable between a contact and any one or more other pairs of contacts. Although the described embodiment uses a leadframe attached to a dielectric film, other structures can be used, for example contacts are formed on both sides of the printed circuit board by etching. It will be appreciated that the contacts may be printed on the dielectric film or circuit board, for example by screen printing a metal pattern. Such a structure is considered to be included within the technical scope of the present invention.

────────────────────────────────────────────────── ─── Continuation of front page    (72) Inventor Stanton, Kevin             United Kingdom, N15.5 AZ,             Northamptonshire, Kettering, Sen             To John's Road 149

Claims (1)

[Claims] 1. For an electrical connector including four or more contacts extending between an input terminal and an output terminal Be careful   Of the furthest contacts of different specific assigned signal transmission pairs of said contacts Overlap causes capacitive coupling between them, resulting in different allocated signals. Induced interference between the nearest contacts of the signal transmission pair and the opposite interference, An electrical connector characterized in that it is configured to reduce physical interference. 2. Each of the furthest contacts is overlaid by another cooperating contact of another pair, It has a lateral extension between them that creates overlap and capacitive coupling. The electrical connector according to claim 1, wherein: 3. The other of the furthest contacts is a large surface with overlapping lateral extensions. Characterized by having a product part, thereby increasing the capacitive coupling between them. The electric connector according to claim 2. 4. The contacts are transversely spaced from the connector and are The furthest one is assigned as one signaling pair, the lateral extension is inward The electrical connector according to claim 2 or 3, wherein the electrical connector extends in a direction. 5. It includes a large number of contacts, and any four or more of the contacts can be selected as a pair. Selected and overlapped by another pair of furthest contacts, between them Interference induced between the closest contacts of another pair, causing capacitive coupling in the 5. The electric power generation system according to claim 1, which induces interference opposite to the above. Damn connector. 6. Two additional signaling pairs of contacts, one on each side of the four contacts. The outer contacts of the four contacts that are arranged are the furthest of the closest additional pair Overlapping contacts to create a bond between them and the contact outside of it Induces the opposite and the induced interference between and the closest terminal of its additional pair The electrical connector according to claim 4, wherein the electrical connector is configured as follows. 7. A contact is an isolation device that forms a dielectric between the overlapping contacts. 7. Any one of the claims 1 to 6 is provided on both sides of the The electrical connector according to item 1. 8. 8. The electric separator according to claim 7, wherein the insulation separation device is a polyimide thin film. Damn connector. 9. The contacts are stamped from a sheet of conductive material mounted on both sides of the isolation device. Formed as a part of a plurality of lead frames that are Item 7. The electrical connector according to Item 7 or 8. 10. One end of the contact is forked to form an insulation displacement connector. The electrical connector according to claim 9, wherein 11. 11. The other end of each contact is an elongated tail. Electrical connector as described. 12. The insulation separation device with the lead frame is Housed in a stick material, characterized in that the ends of the contacts project from it The electrical connector according to claim 11, wherein 13. The ends defining the insulation displacement connector are bent upwards at a substantially right angle, 13. The electric core according to claim 12, wherein the cable is bent downward and rearward of the container. Nectar. 14． A container of plastic material to receive the end of the wire to be terminated Individual slots that extend substantially parallel to each other in a straight line coincident with the insulation displacement connector. 14. It is formed as a rectangular block with a hood. Mounted electrical connector. 15. The square block is slidable by inserting the end that supports the tail. An insulating housing is provided that is shaped to receive the It has slots that are evenly spaced from the tail protruding from the Lot receives each tail when the tail end of the block is inserted and is inserting Guide the tails and separate them after insertion so that the tails receive the mating connectors. The contacts are held in an inclined arrangement as contacts in the openings on both sides of the housing. The electrical connector according to claim 14, which is a characteristic. 16. It has a rectangular shape similar to a rectangular block and receives the insulation displacement connector end Of the block to support and allow it to slide with the block into the housing A strain relief element with similar slots forming an effective extension is provided The electrical connector according to claim 15, wherein the electrical connector is provided. 17． The housing and block or strain relief element Includes cooperating latch portion to hold block and strain relief element during housing The electrical connector according to claim 15 or 16, characterized in that. 18. The housing is open at the top and can be closed over the housing The edged wire is placed in the slot in the block or block and strain relief. Formations that, when placed, combine with them to force wires into the insulation displacement connector 18. A lid having a minute portion, comprising: Electrical connector. 19. 19. The lid of claim 18, wherein the lid is hinged to the housing. Mounted electrical connector. 20. There is an outer shell that allows the housing to be pushed in and adapted, Inserting the housing effectively closes the lid and ties the formation on the lid to the insulated wire. 20. Mating and pushing them into one of the insulation displacement connectors. Electrical connector as described. 21. 21. The outer shell of claim 20, wherein the outer shell is formed of metal. Electrical connector. 22. Insulation displacement connector forks have different heights, In contact with those particular insulated wires during the insulation and insulation displacement due to downward pressure Is done gradually, thereby reducing the required connection force. The electrical connector according to any one of claims 13 to 21.